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Author: Shirshendu Paul Publisher: ISBN: 9781321254129 Category : Drug delivery systems Languages : en Pages : 368
Book Description
Micron- to nanometer - sized ultrasound agents, like encapsulated microbubbles and echogenic liposomes, are being actively developed for possible clinical implementations in diagnostic imaging and ultrasound mediated drug/gene delivery. Contrast microbubbles (1-10 micron in diameter) contain a low solubility gaseous core stabilized by an encapsulation made of lipids/proteins/polymers/surfactants. Echogenic liposomes (ELIPs), which combine the advantages of liposomes such as biocompatibility and ability to encapsulate both hydrophobic and hydrophilic drugs with a strong reflection of ultrasound, are also excellent candidates for concurrent ultrasound imaging and drug delivery applications. The primary objective of this thesis is to characterize the acoustic behavior and the ultrasound-mediated content release of these contrast agents for developing multi-functional ultrasound contrast agents. The first part of this thesis reports the investigation of encapsulated microbubbles utilized as ultrasound contrast agents, whereas the second part reports the experimental characterizations of echogenic liposomes (ELIPs) and echogenic polymersomes. Contrast microbubbles are nonlinear systems capable of generating a subharmonic response i.e., response at half the excitation frequency, which can improve image quality by providing a higher signal to noise ratio. However, design and development of contrast microbubbles with favorable subharmonic behavior requires accurate mathematical models capable of predicting their nonlinear dynamics. To this goal, 'strainsoftening' viscoelastic interfacial models of the encapsulation were developed and subsequently utilized to formulate a modified form of the Rayleigh-Plesset equation to model the nonlinear dynamics of these encapsulated microbubbles. A hierarchical twopronged approach of modeling -- a model is applied to one set of experimental data to obtain the model parameters (material characterization), and then the model isvalidated against a second independent experiment -- is demonstrated in this thesis for two lipid coated (Sonazoid"!and Definity®) and a few polymer (polylactide) encapsulated microbubbles. We performed in vitro acoustic characterization with these contrast microbubbles, i.e., determined the material properties of their encapsulations and compared model predictions with experimental observations. The nonlinear elastic models developed were successful in predicting several experimentally observed behaviors e.g., low subharmonic thresholds and "compression-only" radial oscillations. Results indicate that neglecting the polydisperse size distribution of contrast agent suspensions, a common practice in the literature, can lead to inaccurate predictions and unsatisfactory results. Recent numerical investigations of the nonlinear dynamics of encapsulated microbubbles from our group contradicted previously published experimental results on the dependence of subharmonic behaviors on ambient pressure. We wanted to investigate this issue through new in vitro acoustic experiments by designing a modified experimental setup. Preliminary results indicate that the previously published conclusion that subharmonic response from contrast microbubbles linearly decreases with increasing ambient pressure might not be correct under all excitation conditions; it may both increase or decrease under appropriate excitations in conformity with the results of numerical investigations. Experimental characterization of the ELIPs and polymersomes was performed with the goal of demonstrating their potential as ultrasound agents with simultaneous imaging and drug/gene delivery applications -- 'dual-purpose' contrast agents. Carefully performed experiments conclusively demonstrate the ultrasound reflectivity (echogenicity) of the liposomes prepared using an established protocol. Although, no subharmonic response from these ELIPs was observed, altering the constituents of the lipid bilayer and polymerizing it generated a subharmonic response indicating that the echogenic properties of ELIPs can be controlled by altering the preparation protocol. Our results indicate that the freeze-thaw cycle and lyophilization in presence of mannitol followed by reconstitution in a buffer was critical for generating echogenic response from these liposomes. A finite amount of mannitol (above 100 mM) proved critical for echogenicity, but increasing the mannitol concentration above that amount did not change the echogenicity. Lyophilized powders create a polydisperse suspension of liposomes upon reconstitution, which in turn results in a response without a distinct resonance peak. We believe that the echogenicity of the liposomes results from the larger diameter liposomes present in this polydisperse suspension. In spite of the conclusive experimental evidence of echogenicity, the underlying mechanisms are not completely understood primarily due to the uncertainty regarding the exact location of the gas pockets. An accurate knowledge of the locations and dimensions of the gas pockets is critical for developing improved mathematical models of their acoustic behaviors. For the experimental validation of the concept of 'dual-purpose' contrast agents, four novel formulations were investigated--a lipopeptide conjugated ELIP formulation that can be triggered by the extracellular enzyme matrix metalloproteinase-9 (MMP- 9), a polymer coated redox triggered ELIP formulation for cytosolic drug delivery, pH sensitive liposomes with tunable echogenicity capable of drug-release in mildly acidic micro-environment and redox sensitive echogenic polymersomes. Both in vitro acoustic studies and ultrasound imaging (the latter performed in NDSU by our collaborators) demonstrated the echogenicity of each of these formulations. Although, ultrasound excitation (
Author: Shirshendu Paul Publisher: ISBN: 9781321254129 Category : Drug delivery systems Languages : en Pages : 368
Book Description
Micron- to nanometer - sized ultrasound agents, like encapsulated microbubbles and echogenic liposomes, are being actively developed for possible clinical implementations in diagnostic imaging and ultrasound mediated drug/gene delivery. Contrast microbubbles (1-10 micron in diameter) contain a low solubility gaseous core stabilized by an encapsulation made of lipids/proteins/polymers/surfactants. Echogenic liposomes (ELIPs), which combine the advantages of liposomes such as biocompatibility and ability to encapsulate both hydrophobic and hydrophilic drugs with a strong reflection of ultrasound, are also excellent candidates for concurrent ultrasound imaging and drug delivery applications. The primary objective of this thesis is to characterize the acoustic behavior and the ultrasound-mediated content release of these contrast agents for developing multi-functional ultrasound contrast agents. The first part of this thesis reports the investigation of encapsulated microbubbles utilized as ultrasound contrast agents, whereas the second part reports the experimental characterizations of echogenic liposomes (ELIPs) and echogenic polymersomes. Contrast microbubbles are nonlinear systems capable of generating a subharmonic response i.e., response at half the excitation frequency, which can improve image quality by providing a higher signal to noise ratio. However, design and development of contrast microbubbles with favorable subharmonic behavior requires accurate mathematical models capable of predicting their nonlinear dynamics. To this goal, 'strainsoftening' viscoelastic interfacial models of the encapsulation were developed and subsequently utilized to formulate a modified form of the Rayleigh-Plesset equation to model the nonlinear dynamics of these encapsulated microbubbles. A hierarchical twopronged approach of modeling -- a model is applied to one set of experimental data to obtain the model parameters (material characterization), and then the model isvalidated against a second independent experiment -- is demonstrated in this thesis for two lipid coated (Sonazoid"!and Definity®) and a few polymer (polylactide) encapsulated microbubbles. We performed in vitro acoustic characterization with these contrast microbubbles, i.e., determined the material properties of their encapsulations and compared model predictions with experimental observations. The nonlinear elastic models developed were successful in predicting several experimentally observed behaviors e.g., low subharmonic thresholds and "compression-only" radial oscillations. Results indicate that neglecting the polydisperse size distribution of contrast agent suspensions, a common practice in the literature, can lead to inaccurate predictions and unsatisfactory results. Recent numerical investigations of the nonlinear dynamics of encapsulated microbubbles from our group contradicted previously published experimental results on the dependence of subharmonic behaviors on ambient pressure. We wanted to investigate this issue through new in vitro acoustic experiments by designing a modified experimental setup. Preliminary results indicate that the previously published conclusion that subharmonic response from contrast microbubbles linearly decreases with increasing ambient pressure might not be correct under all excitation conditions; it may both increase or decrease under appropriate excitations in conformity with the results of numerical investigations. Experimental characterization of the ELIPs and polymersomes was performed with the goal of demonstrating their potential as ultrasound agents with simultaneous imaging and drug/gene delivery applications -- 'dual-purpose' contrast agents. Carefully performed experiments conclusively demonstrate the ultrasound reflectivity (echogenicity) of the liposomes prepared using an established protocol. Although, no subharmonic response from these ELIPs was observed, altering the constituents of the lipid bilayer and polymerizing it generated a subharmonic response indicating that the echogenic properties of ELIPs can be controlled by altering the preparation protocol. Our results indicate that the freeze-thaw cycle and lyophilization in presence of mannitol followed by reconstitution in a buffer was critical for generating echogenic response from these liposomes. A finite amount of mannitol (above 100 mM) proved critical for echogenicity, but increasing the mannitol concentration above that amount did not change the echogenicity. Lyophilized powders create a polydisperse suspension of liposomes upon reconstitution, which in turn results in a response without a distinct resonance peak. We believe that the echogenicity of the liposomes results from the larger diameter liposomes present in this polydisperse suspension. In spite of the conclusive experimental evidence of echogenicity, the underlying mechanisms are not completely understood primarily due to the uncertainty regarding the exact location of the gas pockets. An accurate knowledge of the locations and dimensions of the gas pockets is critical for developing improved mathematical models of their acoustic behaviors. For the experimental validation of the concept of 'dual-purpose' contrast agents, four novel formulations were investigated--a lipopeptide conjugated ELIP formulation that can be triggered by the extracellular enzyme matrix metalloproteinase-9 (MMP- 9), a polymer coated redox triggered ELIP formulation for cytosolic drug delivery, pH sensitive liposomes with tunable echogenicity capable of drug-release in mildly acidic micro-environment and redox sensitive echogenic polymersomes. Both in vitro acoustic studies and ultrasound imaging (the latter performed in NDSU by our collaborators) demonstrated the echogenicity of each of these formulations. Although, ultrasound excitation (
Author: L. Hoff Publisher: Springer Science & Business Media ISBN: 9781402001444 Category : Medical Languages : en Pages : 240
Book Description
"The book consists of nine chapters. The first 3 chapters give a broad overview of the acoustic theory for bubble-sound interaction, both linear and nonlinear. Most contrast agents are stabilized in a shell, and this shell can have a strong influence on the interaction between the bubbles and the ultrasound. The effect of the shell is given special attention, as this is not easily found in other bubble literature. Chapters 4, 5, 6 and 7 describe experimental and theoretical methods used to characterize the acoustic properties of the agents, and results of studies on some agents. Chapter 8 shows how the theory and the experimental results can be combined and used to model various phenomena by means of computer simulations. The main purpose of the simulations is to get insight into the mechanisms behind the described phenomena, not to get accurate predictions and values.
Author: Yanjun Gong Publisher: ISBN: Category : Languages : en Pages : 294
Book Description
Abstract: Lipid-coated microbubbles, which have been widely used in diagnostic ultrasound as contrast agents, also show promising applications in medical therapy. The knowledge of acoustic behaviors and shell properties with respect to Ultrasound Contrast Agents (UCA) microbubbles can greatly enhance and extend their clinical applications. A polydimethylsiloxane (PDMS-based microfluidic flow-focusing device was fabricated to produce lipid-coated microbubbles with narrow size distribution and controllable mean diameters (3-12um). These monodisperse microbubbles show unique acoustic properties compared with commercial UCA microbubbles with wide size distribution, which makes it possible to investigate the relationship between microbubble size and attenuation coefficient, resonance frequency, or backscattering experimentally. Our studies show that monodisperse microbubbles can be tailored for optimal contrast enhancement in ultrasound imaging. By using an ultrasound spectroscopy method, the frequency-dependent attenuation coefficient for monodisperse microbubbles and polydisperse microbubbles were measured and compared. The results showed that decreasing the width of the microbubble size distribution would lead to a reduction in the bandwidth, and an increase in the magnitude of the attenuation spectrum. The resonance frequency determined by the attenuation coefficient peak was inversely proportional to the mean diameter of the monodisperse microbubble suspension. These conclusions corroborated the theoretical predications. The dependence of resonance frequency on acoustic pressure and lipid composition have also been examined and compared with theoretical calculations. The results demonstrated that the lipid shell of microbubbles behaviors nonlinearly, even at low pressure, which results in a decrease of resonance frequency as incident pressure was increased, approaching the resonance frequency of uncoated bubbles. Moreover, the length of the lipid hydrocarbon chain impacts the dependences of shell stiffness, attenuation coefficient, and resonance frequency on the excitation pressure. The frequency-dependent backscattering coefficients for monodisperse microbubbles have been investigated using a broadband pulses technique over different sizes, concentrations and pressures. The experimental results showed the same size-dependent resonance peaks as attenuation coefficient. It demonstrated that increasing the acoustic pressure caused a frequency shift of resonance peak, but no significant changes on magnitude. A linear dependence on microbubble concentration for backscatter coefficient was confirmed. In addition, the pressure-dependent backscattering coefficients at 2.25 MHz were studied. It is interesting to note that with the increase of incident pressure, the change of backscattering coefficients values, increase or decrease, were strongly dependent on the mean size of microbubbles.
Author: Aaron Fenster Publisher: Taylor & Francis ISBN: 1439866295 Category : Medical Languages : en Pages : 331
Book Description
Up-to-Date Details on Using Ultrasound Imaging to Help Diagnose Various DiseasesDue to improvements in image quality and the reduced cost of advanced features, ultrasound imaging is playing a greater role in the diagnosis and image-guided intervention of a wide range of diseases. Ultrasound Imaging and Therapy highlights the latest advances in usin
Author: Peter David Bevan Publisher: ISBN: 9780494398593 Category : Languages : en Pages : 328
Book Description
Bubble disruption is associated with the response of ultrasound contrast agents (UCAs) exposed to high acoustic pressures. This behaviour is important for bubble detection techniques as well as flow quantitation and some proposed therapeutic applications. In this thesis, an acoustic system is described for measuring the changing time-course of the echo from a dilute suspension of UCAs exposed to disruptive ultrasound. A model for the echo was also developed, based on literature reports of optically-determined disruption thresholds and a theoretical description of gas diffusion and shrinking bubbles. This describes a physical picture whereby the microbubble shell is disrupted and free gas bubbles are released. The released bubbles may also fragment into multiple daughter bubbles after disruption. Experimental measurements were made for different UCA formulations. Thick polymer-shelled bubbles showed a clear disruption threshold, with a dramatic increase in echo after gas release. Lipid-shelled bubbles demonstrated a disappearance time that depended on the filling gas. As well, the disappearance time depended on the pressure of the disruptive ultrasound pulse. A mathematical model of the post-disruption echo confirmed the importance of microbubble fragmentation in lipid-shelled bubble disruption. Measurements on the clinical contrast agent Definity showed that the post-disruption behaviour depended not only on the pressure but also the frequency and length of the disruption pulses. This final study also demonstrated some of the limitations in the simple mathematical model based on single-bubble observations from the literature. Further work is required to fill the gaps between the model and experimental results. The differences are intrinsically linked to a dearth of knowledge regarding the population distribution of the free gas bubbles released after shell disruption. Furthermore, the disruption threshold of individual bubbles is not understood well enough to predict the population behaviour measured in the experiments presented in this thesis. The results of this work, however, might help to optimize both imaging and therapeutic applications. Also, they could lead to a better understanding of the biophysical mechanisms behind ultrasound-potentiated drug delivery.
Author: Alicia Clark Publisher: ISBN: Category : Languages : en Pages : 115
Book Description
Ultrasound contrast agents are micron-sized bubbles that are used for ultrasound imaging enhancement and that can potentially be used for targeted drug delivery applications. One strategy to manipulate them inside the cardiovascular system is to use the Bjerknes force, caused by the phase difference between a transmitted ultrasound pressure wave and the microbubble volume oscillations induced by the pressure wave. Although the mechanism causing this force is well established, the balance between ultrasound-induced forces and hydrodynamic forces is poorly understood when the microbubbles are immersed in physiologically-realistic Reynolds and Womersley number flows. In this thesis, experiments were conducted in a cylindrical tube under steady and pulsatile flows over a range of Reynolds and Womersley numbers relevant to drug delivery in the systemic circulation. Two experimental setups were developed: one in which the microbubbles were imaged using a clinical ultrasound imaging system, and a second in which they were imaged by high-speed video using a long distance microscope. In the ultrasound experimental setup, a commercial L15-7io transducer was used to image microbubbles in quiescent, steady, and pulsatile flows. These experiments were extended in the optical experimental setup to explore higher Reynolds numbers. In the optical experiments, individual microbubble trajectories were captured at high magnification and high temporal resolution to determine the relationship between acoustic and hydrodynamic forces. The relative scaling of these forces was computed for different acoustic pressure amplitudes and pulse repetition frequencies. The Bjerknes force scaled linearly with pulse repetition frequency and quadratically with acoustic amplitude. The displacement of the microbubbles due to the ultrasound decreased with increasing Reynolds number suggesting a threshold for clinical applications due to the residence time of microbubbles in the ultrasound beam.
Author: Pankaj Jain Publisher: ProQuest ISBN: 9780542817083 Category : Microbubbles Languages : en Pages :
Book Description
Ultrasound contrast agents are micron size bubbles used for medical purposes such as diagnostic ultrasound imaging and targeted drug delivery. These bubbles are encapsulated with a shell and have a sparingly soluble gas inside to prevent them from premature dissolution. When these bubbles are excited by the ultrasound they scatter and absorb energy from the sound field, thus leading to the attenuation of the ultrasound signal. In this thesis, we have developed a viscous and a viscoelastic model for the shell. Attenuation measured in vitro is compared with model predictions to obtain the characteristic model parameters (surface tension, shell elasticity, dilatational viscosity) for commercially available contrast agents. The viscous model predicts unusually high values of surface tension which motivated the viscoelastic model. We have also used both models to predict the scattered response of microbubbles. (Abstract shortened by UMI.).
Author: Shirshendu Paul
Author: Shirshendu Paul
Author: L. Hoff
Author: Yanjun Gong
Author: Aaron Fenster
Author: Peter Johan Anton Frinking
Author: Jeroen Sijl
Author: Peter David Bevan
Author: Alicia Clark
Author: Pankaj Jain
Author: Chao Sun